introduction to analog electrical circuits
DESCRIPTION
Introduction to Analog Electrical Circuits. Richard J. Kozick Electrical Engineering Department. Outline for Today’s Lecture. Fundamental quantities,concepts & units: Charge, current, voltage, power Battery and light bulb: Show actual circuit versus “circuit model” Resistance and Ohm’s Law - PowerPoint PPT PresentationTRANSCRIPT
1 ENGR 100
Introduction to Analog Electrical Circuits
Richard J. Kozick
Electrical Engineering Department
2 ENGR 100
Outline for Today’s Lecture
• Fundamental quantities,concepts & units:– Charge, current, voltage, power
• Battery and light bulb:– Show actual circuit versus “circuit model”
• Resistance and Ohm’s Law
• Kirchhoff’s Laws; series & parallel circuits
• Voltage divider– Light dimmer, volume control, sensors, ...
3 ENGR 100
Technical Subdivisions of EE
• Computer Systems
• Electronics
• Electromagnetics
• Electric Power Systems
• Signal Processing and Control Systems
• Communication Systems
4 ENGR 100
Talk with neighbors and define ...
• What is electric charge?
• What is electric current?
• What is electric voltage?
[Note these are things we can’t see or feel directly!]
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Charge
• Property of matter
• Two kinds, + and -
• Electrical forces:– Opposite charges attract, like charges repel– Force varies as inverse square of distance
between charges (like gravitational force)
• Basis for all electrical phenomena
• Unit: coulomb (C)
6 ENGR 100
Current
• Charges can move
• Current = flow rate of charge
• Unit: ampere (A) = C/s
• Example:– A battery is a supply of charges– Larger current drains the battery faster
7 ENGR 100
Voltage
• Potential energy per unit charge– Arises from force between + and - charges
• Unit: volt (V) = Joule/coulomb = J/C
• Analogy with gravitational potential energy:– P.E. = m • g • h– P.E. per unit mass = g • h
• Need a reference to measure voltage:– Analogous to the floor in auditorium– Common voltage reference is ground (earth)
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Power
• Power = flow rate of energy (W = J/s)
• Current = flow rate of charge (A = C/s)
• Voltage = P.E. per unit charge (V = J/C)
• Say we have a flow of charges (current) that are “giving up” their P.E.:– Power = ??? (W = J/s)
9 ENGR 100
Power
• Power = flow rate of energy (W = J/s)
• Current = flow rate of charge (A = C/s)
• Voltage = P.E. per unit charge (V = J/C)
• Say we have a flow of charges (current) that are “giving up” their P.E.:– Power = Voltage × Current (W = J/s)
10 ENGR 100
Battery and Light Bulb
• Operation of actual circuit
• Circuit model:– Ideal voltage source for battery (9 V always)– “Resistor” to model light bulb (R ohms)– Ideal wires
(0 resistance)9 V
Ir
R
+
-Vr
Ground
11 ENGR 100
Ohm’s Law
• Resistance:– Characterizes “ease” of charge flow (current)– Depends on material and geometry of wire
• Ohm’s Law:
Vr = Ir • R 9 V
Ir
R
+
-Vr
Ground
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• Georg Simon Ohm (1826):– First clear definition of
voltage and current– Showed voltage and
current are related – Then he lost his job and
was ridiculed!– Finally, he became a
university professor in 1849
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More on Battery and Light Bulb
• Vr = _____
• Measurement: Ir = ______
• Power dissipated by bulb:P = _____________
• Ohm’s Law: Vr = Ir • R
• R = _____________
9 V
Ir
R
+
-Vr
Ground
14 ENGR 100
More on Battery and Light Bulb
• Vr = 9 V
• Measurement: Ir = ______
• Power dissipated by bulb:P = _____________
• Ohm’s Law: Vr = Ir • R
• R = _____________
9 V
Ir
R
+
-Vr
Ground
15 ENGR 100
More on Battery and Light Bulb
• Vr = 9 V
• Measurement: Ir = 32.5 mA
• Power dissipated by bulb:P = _____________
• Ohm’s Law: Vr = Ir • R
• R = _____________
9 V
Ir
R
+
-Vr
Ground
16 ENGR 100
More on Battery and Light Bulb
• Vr = 9 V
• Measurement: Ir = 32.5 mA
• Power dissipated by bulb:P = Vr • Ir = 0.29 W
• Ohm’s Law: Vr = Ir • R
• R = _____________
9 V
Ir
R
+
-Vr
Ground
17 ENGR 100
More on Battery and Light Bulb
• Vr = 9 V
• Measurement: Ir = 32.5 mA
• Power dissipated by bulb:P = Vr • Ir = 0.29 W
• Ohm’s Law: Vr = Ir • R
• R = Vr / Ir = 277 ohms
9 V
Ir
R
+
-Vr
Ground
18 ENGR 100
More on Battery and Light Bulb
• Vr = 9 V
• Measurement: Ir = 32.5 mA
• Power dissipated by bulb:P = Vr • Ir = 0.29 W
• Ohm’s Law: Vr = Ir • R
• R = Vr / Ir = 277 ohms
• What if we use an 18 V battery?
9 V
Ir
R
+
-Vr
Ground
19 ENGR 100
Kirchhoff’s Current Law (KCL)
• “The total current entering a node equals the total current leaving a node.”
• Why? Because charge is conserved (neither created nor destroyed), and charge is not accumulated at nodes.
• Find I1, I2, I3:9 V
I1
Ground
I2 I3
4 A 2 A 1 A
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Kirchhoff’s Current Law (KCL)
• “The total current entering a node equals the total current leaving a node.”
• Why? Because charge is conserved (neither created nor destroyed), and charge is not accumulated at nodes.
• Find I1, I2, I3:9 V
2 A
Ground
1 A 1 A
4 A 2 A 1 A
21 ENGR 100
Kirchhoff’s Voltage Law (KVL)
• “Around any closed loop, the sum of voltage rises equals the sum of voltage drops.”
• Why? Energy is conserved!
• Find Va and Vb 9 V
+ -5 V + -1 V
+ +
- -
Va Vb
22 ENGR 100
Kirchhoff’s Voltage Law (KVL)
• “Around any closed loop, the sum of voltage rises equals the sum of voltage drops.”
• Why? Energy is conserved!
• Find Va and Vb 9 V
+ -5 V + -1 V
+ +
- -
4 V3 V
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More Light Bulb Circuits
• Bulbs in series • Bulbs in parallel
How does power per bulb compare with single bulb?
9 VR
9 V R
+
-
Ground
R
+
- R
24 ENGR 100
Single Bulb
9 V
Ir
R
+
-Vr
Ground
Vr = 9 V
Measurement: Ir = 32.5 mA
Power dissipated by bulb:P = Vr • Ir = 0.29 W
R = Vr / Ir = 277 ohms
25 ENGR 100
More Light Bulb Circuits
• Bulbs in series
• P = (Vr / 2) • (Ir / 2 ) = 1/4 power
• Bulbs in parallel
• P = Vr • Ir = same power
For parallel, battery provides twice as much power.
9 V
Ir / 2R
9 V
Ir
R
+
-Vr
Ground
R
+
-Vr / 2
R
26 ENGR 100
Voltage Divider
• Important building block of analog circuits– Behind most “knob” and “slider” controls!– Light dimmer, volume control, treble/bass, …– Used for “filters” (equalizers, crossovers)– Basis for sensors (temperature, light, …)
• Easy to derive equations using KCL, KVL, and Ohm’s Law (please try it if interested)
27 ENGR 100
Voltage Divider
Vs
+ -V1
+
-
V2
SourceVoltage
R1
R2
Describes the “split” of source voltage across series resistors:
ss VRR
RVV
RR
RV
21
22
21
11
28 ENGR 100
Application: Light Dimmer
• Potentiometer (POT) = variable resistor as turn knob (from 0.2 ohms to 5,000 ohms)
• If RPOT = 0.2 ohms:
– VPOT ~ _______
– Vr ~ _______
• If RPOT = 5 k ohms:
– VPOT ~ _______
– Vr ~ _______
9 V
+ -VPOT
+
-
Vr
BatteryRPOT
R =
277
LightBulb
29 ENGR 100
Application: Light Dimmer
• Potentiometer (POT) = variable resistor as turn knob (from 0.2 ohms to 5,000 ohms)
• If RPOT = 0.2 ohms:
– VPOT ~ 0 V
– Vr ~ 9 V , Bulb is ON
• If RPOT = 5 k ohms:
– VPOT ~ _______
– Vr ~ _______
9 V
+ -VPOT
+
-
Vr
BatteryRPOT
R LightBulb
30 ENGR 100
Application: Light Dimmer
• Potentiometer (POT) = variable resistor as turn knob (from 0.2 ohms to 5,000 ohms)
• If RPOT = 0.2 ohms:
– VPOT ~ 0 V
– Vr ~ 9 V, Bulb is ON
• If RPOT = 5 k ohms:
– VPOT ~ 9 V
– Vr ~ 0 V , Bulb is OFF
9 V
+ -VPOT
+
-
Vr
BatteryRPOT
R LightBulb
31 ENGR 100
Application: Heat and Light Sensors
• Sensor resistance Rsensor varies with physical property– Thermistor (temperature)– Photoresistor (light)
• R1 is a fixed resistor
• Then Vsensor changes withtemperature or light!
• Bonus on HW: how to choose R1 ?
Vsensor9 V
+
-
Battery
R1
Rsensor
32 ENGR 100
Concluding Remark
• Hopefully electric circuits are a little bit less mysterious to you now!